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Published by capintec, 2018-02-21 19:51:04

CRC-25R Manual

CRC-25R Manual

CAPINTEC, INC CRC®-25R

PHOTONS

Photon is the general term for a quantum of radiation. Photons are classified according to
their method of production.

γ-Rays

Photons resulting from nuclear transitions, nuclear reaction or annihilation of particles (e.g.,
electron-positron annihilation) are called Gamma-rays (γ-rays). Radioisotope sources
(radionuclides) are the most common means of γ-ray production. Radioisotope γ-sources
emit photons of one or more discrete energies.

X-Rays
X-rays are associated with the deceleration of electrons or with orbital electron transitions in
atoms.

The radiation from a γ-source is often accompanied by characteristic x-rays from transitions
of the orbital electrons in the daughter atom.

Bremsstrahlung
When very fast electrons are brought to rest in a medium (or pass through media) a
continuous low energy photon spectrum occurs. This is called Bremsstrahlung (“stopping or
braking radiation”).

The intensity and the energy spectrum of Bremsstrahlung are highly dependent upon the
source configuration and media surrounding the sample.

In this manual, the term photon will be used when the method of production of the radiation
has no bearing on the discussion.

Interactions of Photons with Matter

There are three mechanisms by which photons can interact with matter and, thus, deposit
their energy. These mechanisms are: Photoelectric effect, Compton Effect, and, pair
production. The energy of the photon determines which process (or processes) is possible.

Photoelectric Effect
The photoelectric effect is an interaction between a photon and an electron that is
bound to an atom. In the photoelectric process, the photon is absorbed by the atom
and a bound electron is ejected. The kinetic energy of the ejected electron is equal to
the photon energy minus the binding energy of the electron. The binding energy of an
electron is the energy that must be supplied in order to remove the electron from the
atom.

In nuclear medicine, we are interested in photon energies of 20keV or greater. At
these energies, all the electrons in the materials used for the chambers are able to

April 16 APPENDIX I I-5

CAPINTEC, INC CRC®-25R

participate in the photoelectric process. The photoelectric effect is the most important
process at low energies. However, for photon energies much greater than electron
binding energies, the processes described below become more important and the
number of photoelectric interactions occurring becomes small. At a given energy, the
number of photoelectric interactions per unit mass varies as the 4th power of the
atomic number and is inversely proportional to the atomic weight of the medium
(Z4/A).

Compton Effect

The Compton Effect is a collision between a photon and an electron that can be
considered unbound. An electron can be considered to be unbound (or “free”) if the
energy of the incident photon is much greater than the binding energy of the electron.
The kinetic energy of the scattered electron is not constant, but is a function of the
angle through which it is scattered. The scattered photon must interact again in order
to impart all of its energy to the medium.

The Compton Effect is the dominant process for photon energies from 100keV to
about 10MeV in the region of the atomic numbers for detector materials. At 100keV,
the maximum kinetic energy of the scattered electron is about 30 percent of that of
the incident photon; at 1MeV, it is about 80 percent; and at 10MeV, it is about 98%.
The number of Compton interactions per unit mass varies directly as the atomic
number and inversely as the atomic weight of the medium (Z/A).

Pair Production

The process of pair production is difficult to comprehend because it is strictly a
relativistic quantum mechanical effect. What is observed to take place is that in the
presence of the electric field of a nucleus, the incident photon disappears and an
electron and a positron appear. (A positron is a particle with the same properties as
an electron, except that it has a positive charge.)

In order to produce an electron-positron pair, the incident photon must have an
energy of at least twice the mass of an electron, i.e., 1.022MeV. This process
dominates for very high energies, that is, above about 10MeV. The number of pair
production interactions per unit mass is proportional to the square of the atomic
number and inversely proportional to the atomic weight of the medium (Z2/A).

IONIZATION CHAMBER MEASURING PROCESS

An ionization chamber consists of two or more electrodes. The electrodes confine a volume
of gas and collect the charge (ions) produced by radiation within the volume. Thus, ionization
chambers can be used to measure radiation fields if the relationship between the radiation
field and the charge produced is known.

The radiation enters the chamber through the chamber wall and interacts with the gas in the
chamber or with the chamber wall. It must be pointed out that photons cannot produce
ionization directly, but must first interact with the chamber material (gas and wall) producing
electrons. That is, through a series of interactions, the photon transfers its energy to one or
more electrons.

I-6 APPENDIX I April 16

CAPINTEC, INC CRC®-25R

The electron is slowed down through collisions with the chamber gas (argon). The collisions
knock electrons off the molecules producing positive ions (this is the ionization process).

The collection voltage across the chamber sets up an electric field. The positive ions will drift
towards the negative electrode and the electron (and negative ions if they are formed) will
drift towards the positive electrode, thus producing a current. The electronic circuitry then
measures either the current or the total charge produced during the period of interest.

The number of ions produced in the chamber is directly related to the energy deposited in the
chamber by the radiation.

DETAILED DISCUSSIONS
Effects of the Integral Shield

The advantage of the shield is the reduction of radiation exposure to the personnel handling
the radioisotopes, as well as reduction of the background effects on the activity
measurements.

It is important to note, however, that if a shield is placed around or near a calibrator, the
sensitivity of the ionization chamber is enhanced due to backscattering of photons by the
shielding. Above about 250keV, the scattering of photons is mainly forward and at the low
energy region, attenuation of photons by the outer wall of the chamber becomes significant.
For a CRC calibrator, the backscattering effects are more significant for photons of energies
between 70keV and 250keV than photons in other energy regions.

Effects of the Container

The radioactive standard materials in the ampoules now being provided by NIST are a good
approximation to an assay of a radiopharmaceutical in a plastic syringe or in a glass syringe
(a wall thickness of about 1.2mm), even for radioisotopes that decay with a significant
abundance of low-energy photons.

The user should select, whenever possible, a standardized procedure, volume, and container
for all radioactivity measurements. The plastic syringe is convenient since it represents the
delivery vehicle to the patient in most clinical situations.

Significant errors will occur in some instances, e.g., if the radioisotope is assayed in an
appreciably different material and/or wall thickness than that of the standards.

The ampoules of recently available standards from NIST are uniform. Plastic syringes also
have a rather uniform wall thickness and absorption is low. However, a random sampling of
5, 10, 25, 50, and 125ml size multi-injection dose vials from several sources indicated that
the wall thickness varied randomly from 1 to 3mm quite independently of the volume of glass
vial.

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CAPINTEC, INC CRC®-25R

The assay of radioisotopes having a significant abundance of low- energy gamma-, x-,
and/or high-energy beta-ray radiation may be affected by changes in the sample
configuration used to assay the radio-pharmaceutical if the samples are severely different
from the standard source. In such cases, an independent check or determination of a
calibration appropriate to a user's needs is advised. Fortunately, most radioisotopes can be
accurately assayed independently of the sample size.

Effects of Impurities

An Ionization chamber itself does not have intrinsic energy- discrimination capability. The
presence of radioisotope impurities will affect the reading of the instrument unless the effect
of impurities is eliminated by photon filtration as is done with Mo99 breakthrough in Tc99m.
However, the presence of low-level radionuclide impurity does not negate the usefulness of a
radioisotope calibrator, if the user is aware of its presence and has an independently
determined calibration including photons arising from the impurities.

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CAPINTEC, INC CRC®-25R

APPENDIX II

CALIBRATION NUMBERS

DETERMINING CALIBRATION SETTING NUMBERS ...................................II-1
Response and Sensitivity ..........................................................................II-1
Calibration Setting Numbers .....................................................................II-2

CALIBRATION SETTING NUMBERS .............................................................II-4
ABBREVIATIONS USED IN TABLE I .............................................................II-5
UNCERTAINTY DUE TO SYRINGE CORRECTION .......................................II-5
UNCERTAINTY DUE TO PUBLISHED DATA.................................................II-5
HALF-LIFE ......................................................................................................II-6
REFERENCES ................................................................................................II-6
TABLE I...........................................................................................................II-7

DETERMINING CALIBRATION SETTING NUMBERS
A method of determining a calibration setting number is described in this section.1

Response and Sensitivity

It is very convenient to express the response of the detector to a radioisotope, A, relative to
that of a standard reference material, e.g. Co60.

 Detector Output due to Sample A 
Activity of Sample A
RA ≡ (1)
 Detector Output due to SRM Co60 
Certified Activity of SRM Co60

The sensitivity of the detector for a photon of energy Ei is defined as:

Si ≡ Detector Output due to 3.7 ×1010 Photons of Ei (2)
Detector Output due to one Curie of Co60

The detector response and the sensitivity have the following relation: (3)

∑R i ≡ Ii Si
i

1 See Suzuki, A., Suzuki M.N., and Weis A.M.: Analysis of a Radioisotope Calibrator; Journal of Nuclear Medicine Technology
Dec. 1976 for more detailed discussions.

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CAPINTEC, INC CRC®-25R

Where Ii is the intensity of the photon whose energy is Ei.

The procedure is to measure the response of the detector to all the available primary
standard samples and to establish the sensitivity of the detector as a function of photon
energy so as to satisfy equation (3) for all standards.

Once the sensitivity curve has been determined, the response of the detector to any
radioisotope may be calculated using equation (3), provided that the decay data are known.

The sensitivity curve for a CRC® Ionization Chamber is given in Figure II-1.

The figure depicts the sensitivity of the ionization chamber as a function of photon energy up
to 1.9MeV. Above a photon energy of 200keV, the ionization in the chamber is mainly due to
electrons resulting from Compton scattering of photons by the filling gas (argon) and the
chamber walls (aluminum).

The peak in the low-energy region of the sensitivity curve is due to the rapid increase in
photoelectric effect as photon energy decreases and to the attenuation of low energy
photons by the sample holder, the chamber liner and the chamber walls, as well as the
absorption of photons in the sample material and its container.

Although a significant fraction of photons with energies below 50keV are stopped in the
chamber wall, some photons could enter the sensitive volume of the chamber and could,
therefore, contribute to the activity measurement. All photons with energies below about
13keV are stopped before they reach the sensitive volume of the chamber and, therefore,
these photons do not contribute to the activity measurement.

Calibration Setting Numbers

The relationship between the response of the detector and the gain setting (relative to that
for Co60, in order for the instrument to give a direct reading of the activity) is given by:

GA ≡ 1 (4)
RA

The calibration setting number is linearly related to the chamber response.

All the calibrators are calibrated with certified Cobalt 60 and Cobalt 57 standard source.

A calibration setting number of 990 was assigned to Co60 and 112 was chosen for Co57.
The calibration setting number of CRC® Calibrator for radioisotope A, NA, is given by:

(( )) (( ))NA =  R A - 1-
RCo60 - RCo57 ∗ NCo60  ∗ N Co60 - N Co57 (5)
N Co60 - N Co57 RCo60 - RCo57

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Entering numerical values:

N Co60 = 990 N Co57 = 112 (6)

R Co60 = 1.000 R Co57 = 0.189 ± 2%

one obtains : NA = 1076(R A − 0.080)

The accuracy of the sensitivity curve and the calibration number determination was tested by
calculating calibration numbers for all the radioisotope standards used for the studies of the
sensitivity. The agreement between the calculated and the observed responses were all
within ±3%.

The accuracy of the chamber response calculation for a particular radioisotope, hence the
accuracy which can be attained by using a calculated Calibration Setting Number depends
not only on the accuracy of the available primary standards used to determine Figure II-1, on
the nuclear data, on the variation in the chamber sensitivity and electrometer gain setting, but
also on the sample configuration due to low energy photon absorption.

The calibration Setting Numbers for pure and equilibrium state radioisotopes for the CRC®
Calibrators are listed in this Appendix. Appendix IV contains tables of multiplication factors
for obtaining the activity of a parent nuclide when it is not in equilibrium with the daughter
nuclide. A general equation for this situation is also given in that appendix.

Since the determination of the Calibration Numbers and the calibrations (normalization) of
the instrument are performed using standard reference materials issued by the NIST and/or
the LMR, the Calibration Numbers for radioisotopes are given for sample configuration
similar to those issued by the NIST.

All of the NIST standards, with the exception of Xe133, were of the liquid solution form.
Approximately 5g of radioactive liquid were sealed in borosilicate glass ampoules having a
diameter of about 17mm, a length of 40mm, and a wall thickness of 0.6mm. The Xe133
standard was sealed together with inactive xenon gas in a borosilicate glass ampoule having
a volume of about 5ml, a length of 45mm, a diameter of 15mm, and a wall thickness of
1.3mm.

April 16 APPENDIX II II-3

CAPINTEC, INC CRC®-25R

CAPINTEC RADIOISOTOPE DOSE CALIBRATOR
CHAMBER SENSITIVITY
Co60 = 1.00

0.6 Y 88

0.5 Co 60
Na 22
0.4 Co 60
0.3
0.2 Bi 207
0.1
Ce 139 Am 241 Y 88
Xe 133 Bi 207 Cs 134
Hg 203
I 125 Xe 133 Cs 137
Cs 134
Co 57 Bi 207
Tc 99m Na 22

Ce 139 Sn 113 : In 113m
Cr 51

Sn 113 Hg 203

Am 241, Co 57

500 1000 1500

PHOTON ENERGY (keV)

Figure II-1

CALIBRATION SETTING NUMBERS
The Calibration Setting Numbers in Table I are applicable to the Capintec Radioisotope
Calibrator only.

The CRC®-25R is a direct reading instrument. No manual multiplication or division should be
performed, even if the Calibration Setting Number is followed by a multiplication sign "×" or a
division sign “÷” and a number.

If the sample contains radioactive impurities, the meter indication will always be higher than
the actual activity of the principal isotope. It will not, however, be the total activity of the
principal isotope and the impurities.

If a Radium Needle is measured, the reading will be lower than the true activity in the needle
due to the shielding effects (filtration) of the needle. To estimate the true activity in a needle,
increase the reading obtained with a calibration number for Ra226 (778) by 2% for each
0.1mm of platinum wall thickness. For example, add 10% to the reading for a 0.5mm wall
platinum needle and add 20% to the reading for a 1.0mm wall platinum needle to estimate
the true Radium activity.

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CAPINTEC, INC CRC®-25R

ABBREVIATIONS USED IN TABLE I

Abbreviation Meaning Abbreviation Meaning
eqb. equilibrium D
S Y days
H seconds E years
M hours exponential, i.e.,
minutes 3E5 = 3 × 105

UNCERTAINTY DUE TO SYRINGE CORRECTION
The Calibration Setting Numbers are given for approximately 5 grams of radioactive solution
in a standard source ampoule made of about 0.6mm thick borosilicate glass. The standard
radioactive source in the ampoule is, however, a good approximation for a
radiopharmaceutical in a plastic syringe or a glass syringe (wall thickness about 1.2mm) for
most radioisotopes.

In general, the attenuation of radiation by a plastic syringe is less than for the standard
ampoule, while for most glass syringes, the attenuation will be greater than for the standard
ampoule.

The anticipated syringe corrections are listed on the table under the column "Uncertainty Due
to Syringe Correction". For example, the required correction for I125 activity is estimated to
be about, ±25%. This means that you should add 25% to the meter reading if the I125 is in a
glass syringe or subtract 25% if it is in a plastic syringe.

Since the attenuation of low energy radiation is very dependent upon the material of the
container, the value given in the syringe correction column should be used mainly as a guide
giving relative magnitude.

If a measurement of activity in a glass vial is anticipated, the container correction for low
energy isotopes will be substantial. It could be about 3 to 5 times that for a syringe.

If no value is given in this column, the correction is not significant, except for a container
differing greatly from the standard ampoule (e.g. very thick glass container, vial made of
glass which contains lead, etc.).

UNCERTAINTY DUE TO PUBLISHED DATA

This is the uncertainty on the value of the activity. From calibration numbers calculated from
decay data, the uncertainty given is calculated using only the reported errors on the intensity
of the γ and/or x-rays. For calibration numbers measured from NBS standard reference
materials (known as SRM;s), the uncertainty given is the reported uncertainty on the activity
of the SRM. For these numbers, the reference is given as NBS (or LMR - Laboratoire de
Metrologie de la Radioactivite - France), and year of source.

April 16 APPENDIX II II-5

CAPINTEC, INC CRC®-25R

HALF-LIFE

The number before the letter is the value of the half-life. The number following the letter is
the reported uncertainty on the half-life.

Examples:

12.34 D1 means 12.34 days ±0.01 days
12.34 D11 means 12.34 days ±0.11 days
12.340 D1 means 12.340 days ±0.001 days
1.234 D1 means 1.234 days ±0.001 days

REFERENCES
This is the source of the data from which the calibration number was calculated. NBS or LMR
means that the calibration number was obtained by measuring a standard reference material
(SRM).

NM75 (Nuclear Medicine 75): L.T. Dillman and F.C. Von Der Lage, Radionuclide Decay
Schemes and Nuclear Parameters for Use in Radiation-Dose Estimation. NM/MIRD
Pamphlet No. 10, 1975.

ORNL76: M.J. Martin Ed., Nuclear Decay Data for Selected Radionuclides. ORNL-5114,
Oak Ridge National Laboratory, March 1976.

NDT70: M.J. Martin and P.H. Blichert-Toft. Radioactive Atoms: Auger-Electrons, α-, β-, γ-
and X-Ray Data. Nuclear Data Tables A, Vol. 8, Nos.1, 2. October, 1970

NDS: Nuclear Data Sheets, Academic Press.

Martin: M. J. Martin. Evaluated Nuclear Data File. Nuclear Data Project. Oak Ridge National
Laboratory.

NCRP-58: National Council on Radiation Protection and Measurement., Report No.58 A
HANDBOOK OF RADIOACTIVITY MEASUREMENTS PROCEDURE.

NUCLIDES and ISOTOPES: Chart of the nuclides. Fourteenth Edition.
General Electric Company Nuclear Energy Operations. Rev. 1989

NIST, Radionuclide Calibrator Measurements of F18 in a 3ml Plastic Syringe. Applied
Radiation and Isotopes. 66, 988-993, J.T. Cessna, M.K. Schultz, T. Leslie, N. Bores, 2008

II-6 APPENDIX II April 16

CAPINTEC, INC CRC®-25R

TABLE I

CAUTION: The calibration numbers given in this table are based upon the NIST SRM geometry (5ml of

solution in glass ampoule with 0.6mm wall thickness). Listed numbers should provide an accuracy of ±5%

when compared to a NIST SRM. Different source geometries (e.g. capsules, seeds, ribbons) may require

geometry correction factors or different calibration numbers. However, no warranty of any kind can be

made as to their accuracy, since there are many other uncontrollable factors (as well as the accuracy of the

published data) involved in the determination of the overall accuracy of an assay. Reference previous

sections of this manual for a discussion of some of the conditions under which the calibration numbers are

valid.

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
Number Corr. % Data %

7Be Beryllium 179 x 10 53.284 D 4 NM75

11C Carbon 457 20.38 M 2 ORNL76

13N Nitrogen 457 9.965 M 4 ORNL76

15O Oxygen 462 122.24 S 14 ORNL76

18F Fluorine 472 109.71 M 2 NIST 08

22Na Sodium 957 1.7 2.602 Y 1 NBS73 Ref. for 0.51, 1.27

MeV

24Na Sodium 658 ÷ 2 14.959 H 4 ORNL76

26Al Aluminum 481 ÷ 2 7.2E5 Y 3 ORNL76

27Mg Magnesium 331 9.458 M 12 ORNL76

28Mg Magnesium 719 3 4 20.91 H 3 ORNL76 Pure; NOTE: NM75
yields a Cal. No. of
804

28Al Aluminum 583 2.244 M 3 ORNL76 Pure

28Mg Magnesium 656 ÷ 2 3 4 20.91 H 3 ORNL76 Reading gives 28Mg
(Eqb. 28Al)
Act. in eqb. sample.

Teqb after 15 minutes.

28Al Aluminum 656 ÷ 2 2.244 M 3 ORNL76 Reading gives 28Al Act.
in eqb. sample. Teqb.
(Eqb. 28Mg) after 15 minutes

28Mg Magnesium 656 3 ORNL76 Reading gives sum of
28Al Eqb. 28Mg & 28Al activity in
Aluminum equilibrium sample.

32P Phosphorus 750 × 100 1.2 14.29 D 2 NBS76 Estimation use only.
2 36.51 M 4 NDT70
38Cl Chlorine 470
1.28E9 Y 1 NM75
40K Potassium 520 × 10 1.827 H 7 ORNL76

41Ar Argon 468

42K Potassium 033 or 3 12.36 H 1 ORNL76
152 × 2
43K Potassium 430 2 22.3 H 1 ORNL76
44Sc Scandium 938
3.927 H 8 ORNL76

April 16 APPENDIX II II-7

CAPINTEC, INC CRC®-25R

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
44Ti Titanium Number Corr. % Data % ORNL76 Pure; 47Ca decays to
46Sc Scandium 47.3 Y 12 ORNL76 47Sc. Eqb. in 90 days.
47Ca Calcium 514 22 83.79 D 2 ORNL76 Pure; see App. IV for
4.536 D 2 non-eqb.
822
Pure; decays to 49Sc
373 Ref. for 320 keV

47Sc Scandium 026 or 3.351 D 2 ORNL76 Decays to 52Mn
618 × 2 52mMn will contribute to
48V Vanadium 569 ÷ 2 2 15.974 D 3 ORNL76 dose.
49Ca Calcium 956 1.25 8.72 M 2 NDT70
51Cr Chromium 100 × 10 27.702 D 4 NBS76 Decays to 56Co;
52Mn Manganese 676 ÷ 2 5.591 D 3 ORNL76 See App. IV
52mMn Manganese 461 ÷ 2 21.1 M 2 ORNL76
52Fe Iron 374 8.275 H 8 ORNL76 Ref. for 122 keV
Capintec Low Energy
54Mn Manganese 309 312.14 D 5 ORNL76 Reference.
55Fe Iron 374
55Co Cobalt 481 2.72 Y 2 ORNL76 Ref. for 1.17, 1.33
56Co Cobalt 648 ÷ 2 MeV Capintec High
56Ni Nickel 844 7 17.54 H NDS76 Energy Reference
Pure
77.9 D 12 NDT70 Pure
Reading gives 62Zn
4 6.1 D 3 NDT70 Act. in eqb. sample.
Eqb. after 1.5 hours.
56Mn Manganese 627 2 2.577 H 1 ORNL76 Reading gives 62Cu
57Co Cobalt 112 1.9 271.7 D 2 NBS76 Act. in eqb. sample.
Eqb. after 1.5 hours.
58Co Cobalt 389 70.82 D 3 ORNL76 Reading gives sum of
59Fe Iron 430 44.51 D 2 ORNL76 62Zn & 62Cu activity in
60Co Cobalt 990 1.0-NBS 5.2714 Y 5 NBS75 equilibrium sample.

1.5-LMR

62Cu Copper 448 9.74 M 2 NM75
62Zn Zinc
62Zn Zinc 217 9.22 H NM75
(Eqb. 62Cu)
62Cu 760
Copper
62Zn (Eqb. 62Zn) 745
62Cu
Zinc 333 NM75
Eqb.
Copper

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Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
64Cu Copper Number Corr. % Data % ORNL76 Decays to 73As.
12.701 H 2 Estimation use only.
65Zn Zinc 015 or 2 ORNL76 Pure
66Ga Gallium 115 × 2 4 243.9 D 1 ORNL76 Pure
67Cu Copper 172 1.4 9.40 H 7 ORNL76 Reading gives act. of
67Ga Gallium 903 2.575 D 3 NBS78 81Rb or 81mKr in
68Ga Gallium 052 2 3.261 D 1 ORNL76 equilibrium sample.
69mZn Zinc 100 43 68.0 M 2 ORNL76 Eqb. after 2 minutes.
72As Arsenic 416 13.76 H 3 ORNL76 Decays to 85Kr
72Ga Gallium 143 5 26.0 H 1 ORNL76
73As Arsenic 795 2.5 14.10 H 1 ORNL76 Pure
73Se Selenium 470 ÷ 2 6 80.30 D 6 ORNL76 Pure
74As Arsenic 324 × 10 26 7.15 H 8 ORNL76
75Se Selenium 748 3 17.78 D 3 NBS75
76As Arsenic 304 3 119.8 D 1 ORNL76
77As Arsenic 258 26.32 H 7 ORNL76
77Br Bromine 110 38.8 H 3 ORNL76
79Kr Krypton 481 × 100 56 H 2 ORNL76
81Rb Rubidium 091 35.04 H 10 NM75
81mKr Krypton 050 4.58 H NM75
81Rb Rubidium 174 13 S 1
Eqb. 915 × 10
81mKr Krypton
270 NM75
82Br Bromine
82Rb Rubidium 536 ÷ 2 2 35.34 H 2 ORNL76
84Rb Rubidium 504
85mKr Krypton 347 1.273 M 2 NM75
85Kr Krypton 065
85Sr Strontium 031 × 100 32.77 D 4 NM75
86Rb Rubidium 193
86Y Yttrium 411 × 10 1 4.480 H 8 ORNL76
86Zr Zirconium 711 ÷ 2
87Kr Krypton 167 2 10.72 Y 1 ORNL76
87mSr Strontium 250
87Y Yttrium 095 1.0 64.854 D 3 NBS75
170
18.64 D 2 ORNL76

14.74 H 2 ORNL76

18 3 16.5 H 1 ORNL76

6 76.3 M 5 ORNL76

2.805 H 3 ORNL76

1 80.3 H 3 ORNL76

April 16 APPENDIX II II-9

CAPINTEC, INC CRC®-25R

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
Number Corr. % Data % Reading gives 87Y Act.
in eqb. sample. Eqb.
87Y Yttrium 357 ORNL76 after 18 hours.
(Eqb. 87mSr) Reading gives sum of
87Y 341 2 ORNL76 87Y & 87mSr activity in
Yttrium equilibrium sample.
87mSr Eqb. 189 14 17.8 M 1 ORNL76
88Rb Strontium 465 ÷ 2 Estimation use only.
88Y 768 1.8 106.61 D 2 NBS73 Almost pure β decay.
89Rb Rubidium 48 × 10 Estimation use only.
90Y Yttrium 850 × 10 1 15.2 M 1 ORNL76
91Y Rubidium Pure
Yttrium 64.0 H 1 NIST92 Pure
Yttrium Reading gives sum of
58.5 D 4 NDT70 95mNb & 95Nb activity in
equilibrium sample.
94Nb Niobium 673 2.03E4 Y 16 ORNL76 Eqb. after 2 years.
95Nb Niobium 285 34.97 D 1 NDT70
95Zr Zirconium 271 64.02 D 5 NDT70 Reading gives sum of
95Zr Zirconium 95mNb 97Zr & 97mNb activity in
Eqb. 145 3.61 D 1 NDT70 equilibrium sample.
95m95Nb Niobium Eqb. after 10 minutes.
249
97Nb Niobium 72.1 M 7 ORNL76 Decays to 97mTc
97Zr 341 Estimation use only.
Zirconium 12 16.90 H 5 ORNL76
97mNb Eqb. 271
Niobium 116
256 × 10
97mNb Niobium 080 × 5 or 60 S 1 ORNL76
97Ru Ruthenium 246× 10 or
97mTc Technetium 030 × 3.5 15 2 2.9 D 1 ORNL76
99Mo Molybdenum 030 × 4 or 65
(in Std. Mo Kit) 204 × 10 91.0 D NM75
030 × 4 or 2
204 × 10 2 NTS78
165
99Mo Molybdenum NBS78
(in CAP-MAC) 080
99Mo 042 NBS78
Molybdenum
99Mo (in MAC-S) 1.9 65.92 H 2 NBS78
99mTc 2.1 6.007 H 1 NBS76
99mTc Molybdenum 2.1 6.007 H 1 NBS76
(Eqb. 99mTc)

Technetium

Technetium
(in CAP-MAC)

II-10 APPENDIX II April 16

CAPINTEC, INC CRC®-25R

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
Number Corr. % Data %
99mTc Technetium NBS78
(Eqb. 99Mo) 175 2
99Mo Molybdenum
Eqb. 145 2 NBS78 Reading gives sum of
99mTc Technetium 562 × 10 50 99Mo & 99mTc activity in
103Pd Palladium 634 × 10 50 equilibrium sample.
103Pd
Palladium 631 × 100 50 4 16.97 D 2 ORNL76 Pure
103mRh Eqb. 165 50 5 ORNL76
103mRh Rhodium 172 50 5 Reading gives sum of
103Ru 3 56.114 M 6 ORNL76 103Pd & 103mRh activity
103Ru Rhodium 027 or 39.26 D 2 ORNL76 in equilibrium sample.
140 × 2 15 Eqb. after 9 hours.
103mRh Ruthenium 4 ORNL76
106Ru Ruthenium Reading gives sum of
Eqb. 2 369 D 2 NDT70 103Ru & 103m,Rh activity
Rhodium 30 in equilibrium sample.
1.36 Eqb. after 9 hours.
Ruthenium 5 Reading gives 106Ru
(Eqb. 106Rh) 2 Act. in eqb. sample.
3.2 Eqb. after 5 minutes.
106Ru Ruthenium 480 × 10 2 369 D 2 NDT70 Reading gives sum of
Eqb. 106Ru & 106Rh activity
106Rh Rhodium 830 in equilibrium sample.
108mAg Silver 099 × 10
108Ag Silver 047 or 3 127 Y 21 ORNL76 Large β contribution.
109Cd Cadmium 180 × 2 6 2.37 M 1 ORNL76 Reading gives act of
Eqb. 40 462.6 D 4 109Cd, 109mAg, or Total
109mAg Silver ORNL76 Act. in eqb. sample.
109Pd 435 × 10 10 39.8 S ORNL76 Eqb. after 6 minutes.
Palladium 35 13.427 H 14 NBS77 Reading gives act of
109mAg Eqb. 554 ÷ 2 7 39.8 S MARTIN77 109Pd, 109mAg, or Total
110mAg Silver 054 × 10 Act. in eqb. sample.
111Ag 303 15 249.8 D 1 Eqb. after 6 minutes.
111In Silver 022 or 15 7.45 D 1
113Sn Silver 129 × 2 2.805 D 1 For pure 113Sn.
Indium 076 115.08 D 3
Tin
180
113mIn Indium 1.658 H 1 Separated for pure
113Sn 058 NBS73,77 113mIn.
113mIn Tin 4.486 H 4
115mIn Eqb. Reading gives act. of
Indium 113Sn, 113mIn, or Total
Act. in eqb. sample.
Indium Eqb. after 15 hours.

ORNL76

April 16 APPENDIX II II-11

CAPINTEC, INC CRC®-25R

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
116mIn Indium Number Corr. % Data % ORNL76 Pure
117mSn Tin 54.15 M 6 ORNL76 Pure
117Sb Antimony 974 3 13.61 D 4 ORNL76 Reading gives act. of
119mSn Tin 2.80 H 1 ORNL76 121mTe or 121Te in eqb.
121mTe Tellurium 180 15 2 293.0 D 13 ORNL76 sample. Eqb. in 120
121Te Tellurium 154 D 7 ORNL76 days. See App. IV for
121mTe Tellurium 082 32 17 D 1 non-eqb. samples.
Eqb. Reading gives sum of
121Te Tellurium 657 × 10 35 4 121mTe or 121Te in eqb.
sample.
187 12 9
Ref. for 28 keV x-ray.
373 10 3
Pure
645 Reading gives 125Sb
Act. in eqb. sample.
121mTe Tellurium 572 Eqb. after 1 year.
Eqb. Reading gives sum of
121Te Tellurium 146 6 2.70 D 1 ORNL76 125Te and 125mTe in
122Sb Antimony eqb. sample. See App.
123I Iodine 277 15 1.9 13.221 H 3 NBS77 IV for non-eqb. activity.
123mTe Tellurium
124Sb Antimony 177 12 119.7 D 1 NDT70 Pure
124I Iodine Pure
125I Iodine 720 60.20 D 3 ORNL76
125Sb Antimony
125Sb Antimony 570 5 4.18 D 2 ORNL76
(Eqb. 125mTe)
125Sb 319 25 1.45 59.6 D 2 NBS76
Antimony
125mTe Eqb. 289 10 2.758 Y 1 NDT70
125mTe Tellurium
126I 371 12 2.758 Y 1 NDT70
127Xe Tellurium
129mTe Iodine 364 12 NDT70
129Te Xenon
Tellurium 259 25 57.40 D 5 NDT70
Tellurium 240 10
371 12 18 13.02 D 7 ORNL76
817 × 10 20
679 × 10 15 5 36.4 D 1 ORNL76

5 33.6 D 1 ORNL76

13 69.6 M 2 ORNL76

129mTe Tellurium 054 Reading gives act. of
Eqb. 129mTe or total act. in
129Te Tellurium 397 eqb. sample. Eqb. in
129Cs 166 10 hours.
129I Cesium 362
129mXe Iodine 15 20 32.06 H 6 ORNL76 NM75 gives 488
Xenon
20 1.57E7 Y 4 ORNL76

20 3 8.0 D 2 ORNL76

II-12 APPENDIX II April 16

CAPINTEC, INC CRC®-25R

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
130I Iodine Number Corr. % Data % ORNL76 Decays to 131mXe.
131I Iodine 12.36 H 1 NBS76 1.1% feeding.
984 1.65 8.021 D 1
Pure
151 Pure
Reading gives 132Te
131mXe Xenon 089 20 3 11.9 D 1 ORNL76 Act. in eqb. sample.
131Cs Cesium 148 20 Eqb. after 1 day.
131Ba Barium 505 10 3 9.69 D 1 ORNL76 Reading gives 132I Act.
132Te Tellurium 315 10 in eqb. sample.
132I Iodine 999 7 11.8 D 2 ORNL76 Reading gives sum of
132Te Tellurium 675 ÷ 2 132Te and 132I in eqb.
(Eqb. 132I) 5 76.3 H 2 ORNL76 sample.

2.30 H 3 ORNL76 Decays to 133mXe.
Decays to 133Xe. See
132I Iodine 653 ÷ 2 App. IV.
(Eqb. 132Te)
132Te 663 ORNL76 Decays to 133Ba.
Tellurium
132I Eqb. 485 10 2 6.475 D 10 ORNL76 Decays to 134Cs.
132Cs Iodine 225
133I 100 20 20.8 H 1 ORNL76 Decays to 135Xe. See
133mXe Cesium 12 App. IV.
188 12 3 2.19 D 1
Iodine 132 10 Ref: 661.6 & 32.9 keV.
591 3 Reading gives 137Cs or
Xenon 533 15 Total Activity of eqb.
037 or sample. Often referred
133Xe Xenon 160 × 2 3 1.95 5.243 D 1 NBS76 to as "Cs-137" Source.
133mBa Barium 726 2
133Ba Barium 181 15 3 38.9 H 1 ORNL76 Ref: 36.8 keV
134Te Tellurium
134mCs Cesium 085 3 10.5 Y 1 ORNL76
130
489 ÷ 2 6 41.8 M 8 ORNL76

220 2.91 H NM75

134Cs Cesium 2.3 2.065 Y 1 NBS73
135mXe Xenon
15.29 M 3 ORNL76

135Xe Xenon 9.09 H 1 ORNL76
135mBa Barium
136Cs Cesium 4 28.7 H 2 ORNL76
137Cs
Cesium 4 13.1 D 1 ORNL76
137mBa Eqb.
Barium 2.0 30.0 Y 2
NBS73

2.553 M 1

139Ba Barium 445 × 10 5 12 82.8 M 2 ORNL76
139Ce Cerium 352 5
141Ce Cerium 061 5 2.6 137.64 D 2 NBS73

5 32.50 D 1 ORNL76

April 16 APPENDIX II II-13

CAPINTEC, INC CRC®-25R

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
142Pr Praseodymium Number Corr. % Data % ORNL76 Estimation use only. β
144Pr Praseodymium 19.13 H 4 ORNL76 dominant.
226 × 10 14 17.28 M 5 Ref: 36.7 & 133.5 keV.
Reading gives sum of
137 × 10 5 144Ce & 144Pr Act. in
equilibrium sample.
144Ce Cerium 387 × 10 5 2.8 285.0 D 1 NBS73 Eqb. after 2 hours.
144Pr Eqb.
Praseodymium Decays to 188Re. Eqb.
after 7 days. See App.
145Pm Promethium 207 10 3 17.7 Y 4 ORNL76 IV
147Nd Neodymium 213 5 Reading gives 188W
157Dy Dysprosium 424 5 4 10.98 D 1 ORNL76 Act. in eqb. sample.
169Yb Ytterbium 948 3 Eqb. after 5 days.
171Tm Thulium 292 × 100 4 8.1 H 1 NM75 Reading gives 188Re
175Yb Ytterbium 308 × 10 2 Act. in eqb. sample.
177Lu Lutetium 450 × 10 2 2.5 32.03 D 1 NBS78 Reading gives sum of
181Hf Hafnium 387 188W & 188Re activity in
181W Tungsten 165 3 1.92 Y 1 NM75 equilibrium sample.
188W Tungsten 111 × 100
13 4.19 D 1 ORNL76 Ref. for 70 & 77 keV.

7 6.71 D 1 ORNL76

6 42.4 D 1 ORNL76

11 121.2 D 3 ORNL76

69.4 D 5 NM75

188Re Rhenium 496 × 10 16.98 H 2 NM75
188W 522 × 10
Tungsten
(Eqb. 188Re) 516 × 10

188Re Rhenium 217 × 10 9.90 M NM75
(Eqb. 188W)
188W Tungsten 858 2 13 15.4 D 2 ORNL76
Eqb. 250
188Re Rhenium 408 2 73.83 D 1 NDS73
190mOs Osmium 469 × 10 2
191Os Osmium 686 × 10 18 19.15 H 3 ORNL76
192Ir Iridium 197 2
194Ir Iridium 149 6 18.3 H 3 ORNL76
197Pt Platinum 053
197Hg Mercury 205 2.9 64.1 H 1 NBS76
198Au Gold 093
199Au Gold 344 1.65 2.696 D 2 NBS78
201Tl Thallium
203Hg Mercury 6 3.139 D 7 ORNL76
203Pb Lead
2.0 72.91 H 2 NBS76

1.1 46.60 D 1 NBS73

2 51.88 H 1 ORNL76

II-14 APPENDIX II April 16

CAPINTEC, INC CRC®-25R

Radioisotopes Calibration Uncertainty Due to Half-Life Ref. Comments
Setting Syringe Published (NCRP-58)
204Tl Thallium Number Corr. % Data % NDT70 Ref. for 1064, 569.7,
207Bi Bismuth 3.78 Y 2 NBS73 76.7, & 1772 keV.
420 × 100 22 32.2 Y 9
Decays to 212Bi. Eqb.
846 1.7 after 1 hr. See App. IV.

208Tl Thallium 571 ÷ 2 3.053 M 4 NM75 Reading gives 212Pb
212Pb Lead 101 10.64 H 1 NM75 Act. in eqb. sample.
Eqb. after 8 hours.
212Bi Bismuth 489 × 10 60.55 M 6 NM75 Reading gives 212Bi
212Pb Lead 158 Act. in eqb. sample.
(Eqb. 212Bi) Reading gives sum of
212Bi 135 3.66 D 4 NM75 212Pb & 212Bi activity
Bismuth in equilibrium sample.
212Pb (Eqb. 212Pb) 030 or 0.5 1600 Y 7 NBS73
212Bi Lead 146 × 2 Reading in grams.
224Ra Eqb. Commonly referred to
226Ra Bismuth 646 × 100 as "Radium "Source.
Radium 778 1.025 g/Ci of Ra-226.
239Np Radium
241Am + chain of 147 6 2.355 D 4 ORNL76 Ref. for 59.5 & 14 keV.
daughters
055 4 1 432.2 Y 5 LMR69
Neptunium
Americium

April 16 APPENDIX II II-15

CAPINTEC, INC. CRC®-25R

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CAPINTEC, INC CRC®-25R

APPENDIX III

MULTIPLICATION FACTORS FOR NON-
EQUILIBRIUM RADIOISOTOPES

Ca47 Measurements ..................................................................................... III-2
Ni56 Measurements ...................................................................................... III-2
Zn62 Measurements ..................................................................................... III-3
Y87 Measurements ....................................................................................... III-3
Zr95 Measurements ...................................................................................... III-4
Te121m Measurements ................................................................................ III-4
Sb125 Measurements ................................................................................... III-5
Te129m Measurements ................................................................................ III-5
Te132 Measurements.................................................................................... III-6
Xe133m Measurements ................................................................................ III-6
Xe135m Measurements ................................................................................ III-7
W188 Measurements .................................................................................... III-7
Pb212 Measurements ................................................................................... III-8

Note: These Multiplication Factors apply to the R Chamber only.

The activity in a non-equilibrium sample can be determined by using the following equation:

Activity of "A" = Meter Reading with Cal. Number for Pure "A"

1+ F TA  exp  - TA - TB × t × 1n2  RB
TA - TB 1 - TA × TB RA


where “A” and “B” are parent and daughter nuclide respectively, T's are half-lives, and RA
and RB are the chamber responses to the isotopes A and B, “t” is the elapsed time after the
pure parent isotope was produced, and “F” is the decay branching ratio.

The chamber response, “R” may be obtained from the calibration number “N,” using the
following equation:

R = N + 0.0797
1075.8

When the half-life of the parent nucleus (TA) is much shorter than that of the daughter
nucleus (TR), the parent decays down to the daughter. After about 10 × TA, we can assume
that only the daughter is left (except if the original activity of the parent was exceptionally
high). The equation above for the Activity of “A” can be used to obtain the activity of the
parent while it has measurable activity.

April 16 APPENDIX III III-1

CAPINTEC, INC CRC®-25R

Multiplication factors obtained by using the equation are given in the following tables for
selected isotopes.

CA47 MEASUREMENTS

Use a Calibration Number of 373 and a multiplication factor as indicated in the following table
to obtain Ca47 activity at time “t” days after an initially pure source of Ca47 is obtained.

Ca47

t Multiplication t Multiplication
[days] Factor
Factor [days]
0 0.672
1 1.000 12 0.648
2 0.627
3 0.950 14 0.609
4 0.594
5 0.906 16 0.566
6 0.545
7 0.869 18 0.519
8 0.496
9 0.836 20 0.485
10 0.484
0.806 25

0.781 30

0.757 40

0.737 50

0.718 100

0.701 150

NI56 MEASUREMENTS

Use a Calibration Number of 844 and a multiplication factor as indicated in the following table
to obtain Ni56 activity at time “t” days after an initially pure source of Ni56 is obtained.

Ni56

t Multiplication t Multiplication
[days] Factor
Factor [days]
0 0.824
1 1.000 9 0.799
2 0.745
3 0.985 10 0.659
4 0.508
5 0.969 12 0.366
6 0.249
7 0.952 15 0.101
8 0.013
0.934 20

0.915 25

0.894 30

0.872 40

0.849 60

III-2 APPENDIX III April 16

CAPINTEC, INC CRC®-25R

ZN62 MEASUREMENTS

Use a Calibration Number of 217 and a multiplication factor as indicated in the following table
to obtain Zn62 activity at time “t” minutes after an initially pure source of Zn62 is obtained.

Zn62

t Multiplication t Multiplication
[minutes] Factor
Factor [minutes]
0 0.368
10 1.000 45 0.361
20 0.359
30 0.526 60 0.358

0.425 75

0.389 90

Y87 MEASUREMENTS

Use a Calibration Number of 170 and a multiplication factor as indicated in the following table
to obtain Y87 activity at time “t” hours after an initially pure source of Y87 is obtained.

Y87

t Multiplication t Multiplication
[hours] Factor
Factor [hours]
0 0.664
0.25 1.000 5 0.644
0.50 0.618
0.75 0.960 6 0.602
1.00 0.593
1.5 0.926 8 0.582
2.0 0.580
3.0 0.893 10 0.579
4.0 0.579
0.866 12

0.820 18

0.784 24

0.729 48

0.691 ∞

April 16 APPENDIX III III-3

CAPINTEC, INC CRC®-25R

ZR95 MEASUREMENTS

Use a Calibration Number of 271 and a multiplication factor as indicated in the following table
to obtain Zr95 activity at time “t” days after an initially pure source of Zr95 is obtained.

Zr95

t Multiplication t Multiplication
[days] Factor
Factor [days]
0 0.592
2 1.000 40 0.548
4 0.513
6 0.961 50 0.462
8 0.426
10 0.925 60 0.374
15 0.347
20 0.893 80 0.322
25 0.309
30 0.863 100 0.308

0.836 150

0.776 200

0.727 300

0.685 600

0.650 ∞

TE121M MEASUREMENTS

Use a Calibration Number of 187 and a multiplication factor as indicated in the following table
to obtain Te121m activity at time “t” days after an initially pure source of Te121m is obtained.

Te121m

t Multiplication t Multiplication
[days] Factor
Factor [days]
0 0.437
1 1.000 40 0.415
2 0.401
5 0.943 50 0.392
10 0.386
15 0.895 60 0.382
20 0.379
25 0.782 70 0.376
30 0.374
0.661 80

0.586 90

0.535 100

0.499 120

0.472 140

III-4 APPENDIX III April 16

CAPINTEC, INC CRC®-25R

SB125 MEASUREMENTS

Use a Calibration Number of 289 and a multiplication factor as indicated in the following table
to obtain Sb125 activity at time “t” days after an initially pure source of Sb125 is obtained.

Sb125

t Multiplication t Multiplication
[days] Factor
Factor [days]
0 0.878
10 1.000 90 0.861
20 0.849
30 0.977 120 0.841
40 0.824
50 0.958 150 0.822
60 0.821
0.941 180

0.927 360

0.914 540

0.903 ∞

TE129M MEASUREMENTS

Use a Calibration Number of 817 and a multiplication factor as indicated in the following table
to obtain Te129m activity at time “t” hours after an initially pure source of Te129m is
obtained.

Te129m

t Multiplication t Multiplication
[hours] Factor
Factor [hours]
0 6.55
1 10.0 6 6.50
2 6.49
4 8.04 8 6.48
Equilibrium
7.25 10

6.701 12

April 16 APPENDIX III III-5

CAPINTEC, INC CRC®-25R

TE132 MEASUREMENTS

Use a Calibration Number of 315 and a multiplication factor as indicated in the following table
to obtain Te132 activity at time “t” hours after an initially pure source of Te132 is obtained.

Te132

t Multiplication t Multiplication
[hours] Factor
Factor [hours]
0 0.342
0.25 1.000 4 0.318
0.50 0.275
1.00 0.836 5 0.266
2.00 0.265
3.00 0.725 10 0.264
Equilibrium
0.586 15

0.447 20

0.380 24

XE133M MEASUREMENTS

Use a Calibration Number of 100 and a multiplication factor as indicated in the following table
to obtain Xe133m activity at time “t” days after an initially pure source of Xe133m is obtained.

Xe133m

t Multiplication t Multiplication
[days] Factor
Factor [days]
0 0.465
1 1.000 4 0.385
2 0.151
3 0.824 5 0.024

0.680 10

0.562 20

III-6 APPENDIX III April 16

CAPINTEC, INC CRC®-25R

XE135M MEASUREMENTS

Use a Calibration Number of 181 and a multiplication factor as indicated in the following table
to obtain Xe135m activity at time “t” minutes after an initially pure source of Xe135m is
obtained.

Xe135m

t Multiplication t Multiplication
[minutes] Factor
Factor [minutes]
0 0.807
10 1.000 60 0.676
20 0.514
30 0.990 75 0.217
45 0.019
0.975 90

0.952 120

0.897 180

W188 MEASUREMENTS

Use a Calibration Number of 111 and a multiplication factor as indicated in the following table
to obtain W188 activity at time “t” hours (or days) after an initially pure source of W188 is
obtained.

W188

t Multiplication t Multiplication
[hours] Factor
Factor [days]
0 5.09
1 100.0 1 3.75
2 3.40
4 45.6 2 3.30
6 3.26
12 29.9 3 3.25
18 3.24
18.2 4

13.4 5

8.0 6

6.0 7

April 16 APPENDIX III III-7

CAPINTEC, INC CRC®-25R

PB212 MEASUREMENTS

Use a Calibration Number of 101 and a multiplication factor as indicated in the following table
to obtain Pb212 activity at time “t” hours after an initially pure source of Pb212 is obtained.

Pb212

t Multiplication t Multiplication
[hours] Factor
Factor [hours]
0 0.772
0.5 1.000 5 0.768
1.0 0.766
2.0 0.924 6 0.765
3.0 0.765
4.0 0.875 7 0.764
Equilibrium
0.820 8

0.793 9

0.779 10

III-8 APPENDIX III April 16

CAPINTEC, INC CRC®-25R

APPENDIX IV

OPERATIONAL SUMMARY

QUALITY CONTROL & DAILY TESTS ..........................................................IV-1
BACKGROUND ADJUSTMENT ....................................................................IV-1
MEASURING NUCLIDE ACTIVITY ................................................................IV-2

Selecting a Nuclide for Measurement ......................................................IV-2
Future Activity ...........................................................................................IV-3
ENTER TEST SOURCE DATA ......................................................................IV-3

Thank you for choosing CAPINTEC. This “Start-Up” aid is designed to allow you to use the
CRC®-25R to perform immediate nuclide measurements.

QUALITY CONTROL & DAILY TESTS
Prior to making any activity measurements, Daily Tests must be performed.

From the Measurement screen, press TEST . The Tests Menu will appear.

TESTS
1. Daily
2. Chamber Volts
3. Accuracy
4. Enhanced
5. Moly Assay

Select Daily by pressing . The Daily Tests include Auto Zero, Background

Adjustment, Chamber Voltage Test, Data Check, Accuracy and Constancy. You will be

required to perform your normal or manual Accuracy and Constancy tests if you have not
entered your Reference Source data in the CRC®-25R. To input Reference Source data,

refer to CHAPTER 6: CHAMBER INITIALIZATION, SECTION: TEST SOURCES.

BACKGROUND ADJUSTMENT

Background adjustment is performed automatically in the Daily Test sequence. It can also be
performed by pressing the Background key.

To perform a Background Adjustment, press . The following screen will appear.

July 16 APPENDIX IV IV-1

CAPINTEC, INC CRC®-25R

MEASURE
BACKGROUND

NO SOURCES
Any Key to Continue

Make sure that no sources are in the vicinity of the Chamber. Press any key, other than the
HOME key, to begin. When a measurement is ready, the message “OK – ENTER to Accept”
will appear.

Press . The background value will be stored and automatically subtracted from all

measurements.

MEASURING NUCLIDE ACTIVITY
To measure the activity of a sample, simply place the sample in the dipper, lower it into the
Chamber, and select the nuclide from the keypad.

Selecting a Nuclide for Measurement
When measuring the activity of a nuclide, you must indicate the nuclide being
measured. This can be accomplished in four (4) simple ways:

1. PRE-SET NUCLIDE KEYS: There are 8 pre-defined nuclide keys. Each key is
labeled to indicate the corresponding nuclide as shown below.

Example: To measure Tc99m, place the sample in the Chamber and press

. The activity for Tc99m is automatically displayed.

2. USER DEFINED KEYS: There are 5 User defined keys. You can assign nuclides
to these keys. (See CHAPTER 6: CHAMBER INITIALIZATION, SECTION: USER
KEY ASSIGNMENT)

Example: If the assignment for U1 is Co57, place the sample in the Chamber

and press . The activity for Co57 is automatically displayed.

IV-2 APPENDIX IV July 16

CAPINTEC, INC CRC®-25R

3. NUCLIDE KEY: The Nuclide Key allows you to select a nuclide from the list of
nuclides that have been stored in the memory. Simply press the NUCL key and
use the alphanumeric (number/letter) keys to specify the nuclide. After inputting
the values press the ENTER key.

Example: To measure Co60, place the sample in the Chamber and press

. Press . Press .

The activity for Co60 is automatically displayed.

4. CALIBRATION NUMBERS: To measure the activity of a nuclide that is not
stored in the memory, Pre-Set keys, or User defined keys, press the CAL# key,
input the Calibration Number for the nuclide using the alphanumeric
(number/letter) keys, and press the ENTER key. The activity can then be
measured. Simply place the sample in the Chamber.

Note: Calibration Numbers for R Chambers are listed in Appendix II.

Example: Press . Input the Calibration Number. Press .

Future Activity

The CRC®-25R has a special feature that allows you to automatically determine the
activity of a sample at some point in the future. From the Measurement screen, press
TIME.

Example: Press . Input the new time & date in the 24-hour format. Press

. The “FUTURE” activity is displayed.

ENTER TEST SOURCE DATA

(Reference CHAPTER 6: CHAMBER INITIALIZATION, SECTION: TEST SOURCES)
The Test Source Data must be entered from the Main Setup Menu. To access this menu,

press to return to the Measurement Screen. Press to display the Main Menu.

1. Inventory
2. Calculations
3. Diagnostics
4. Setup

Select SETUP. The Setup Menu will appear.

July 16 APPENDIX IV IV-3

CAPINTEC, INC CRC®-25R

SETUP
1. Time
2. Ci/Bq
3. Printing
4. Other
5. Screen

Select OTHER. Input the password (last 3-digits of the readout serial number) and press

ENTER . The Other Menu will appear.

1. User Keys
2. Sources
3. Moly Setup
4. Nuclides
5. Linearity
6. Remote / PC

Select SOURCES. The Test Sources Menu will appear.

1. Co57
2. Co60
3. Ba133
4. Cs137
5. Ra226

6. Constancy

Select Cs137. The system will display

Cs137
[displays Test
source data or
message “NO
SOURCE”]

OK? Y or N

If the Test Source data has been input in the system, verify that these are the dates from
your Cs137 Test Source and press YES. Press NO if the dates are incorrect or if no source
data has been entered in the system.

Input the serial number of the Test Source and press ENTER. Input the Calibration Day and
press ENTER. Input the Calibration Activity and press ENTER. Press YES to answer yes to
“Use Daily?”.

The system will display the entered data. Verify the data and confirm with YES. To correct
any errors, press NO.

Press to return to the Measurement Screen.

For Technical Assistance, contact
Capintec’s only Authorized Service Center at (800) ASK-4CRC.

IV-4 APPENDIX IV July 16

CAPINTEC, INC. CRC-25R

INDEX

A Ci / Bq
Acceptance Testing, 4-9, 7-1 Choosing, 5-3
Accredited Dosimetry Calibration Conversion, 14-2
key, 3-3
Laboratory, 1-3
Accuracy Test, 7-2, 7-3, 8-11 Cleaning, 15-1, 15-2
Cleaning Instructions, 15-2
in Daily Test, 8-8 Constancy Test, 8-8
ADCL, 1-3
Adding to Inventory, 12-2 Source, 4-8, 6-9
adjustments, 1-4 Contamination Test, 7-3
Alphanumeric contrast, 5-17

entering Data, 3-4 screen, 5-19
keys, 3-3
ARROW Keys, 3-3 D
Assembly, 4-3 Daily Test, 7-2, 7-3, 8-3
Auto Zero, 8-4
Accuracy Test, 8-8
B Auto Zero, 8-4
Background, 8-1, 8-5 Background, 8-5
backlight, 5-17, 5-18 Chamber Voltage, 8-6
Battery, 15-14 Constancy Test, 8-8
Data Check, 8-7
low, 15-7 Report, 8-9
Replacement, 15-7 Data Check, 8-7
BKG key, 3-2 Date
Brachytherapy, 1-3, 1-4 entering, 5-1
Decay Calculation, 14-3
C Deleting from Inventory, 12-13
CAL# key, 3-2, 10-4, 14-3 Description
Calculation Utilities, 14-1 Functional, 2-2
Technical, 2-4
Ci /Bq Conversion, 14-2 Diagnostics, 9-1
Decay Calculation, 14-3 Test, 7-2, 7-4
Calibration Numbers, 6-16, 6-19, 10-4 Dimensions, 2-6
changing, 4-8, 6-21 Cables, 2-6
determining, 6-17 Chamber, 2-6
entering, 6-16, 10-4 Console, 2-6
entering new, 6-20 Dipper, 1-4, 4-5, 15-2
Limits, 6-16, 10-5 Disinfecting, 15-2
restoring, 6-23 Disinfecting Instructions, 15-3
Calicheck Test, 11-13 Disposal, 15-5
defining, 6-27 division factors, 1-4
Canister, 4-8, 10-10 Dose Table, 13-1
CapMac, 4-8, 10-10
CE key, 3-3 E
Chamber Initialization, 6-1 Electromagnetic Interference, 1-5
Chamber Measurement Procedures, 10-2 EMC, 2-7
Chamber Voltage, 8-6, 8-10 EMI, 1-5, 5-4

April 16 INDEX i-1

CAPINTEC, INC. CRC-25R

Enhanced Tests, 11-1 Lineator-defining, 6-26
Enhanced Tests Menu, 11-1 performing, 11-7
ENTER key, 3-3 Standard-defining, 6-25
Environment Requirements, 2-4, 4-6 Lineator Test, 11-12
ETL Listed, 2-7 defining, 6-26
Liner, 1-4, 4-5, 15-2
F liners, 15-2
Functional Description, 2-2 Low Activity Measurements, 10-2
Fuse Servicing, 15-6 Low Battery, 1-1, 15-7

G M
Geometry, 7-1 MAG3 Test, 11-25
Geometry Test Main Menu, 5-1, 9-1, 12-1, 14-1
maintenance, 15-1
Measurement Results, 11-6 Measurement
Geometry Test, 11-2
Ground Current, 2-5 Activity at a Different Time, 10-6
Calibration Number, 10-4
H Nuclide Specification, 10-3
HMPAO Test, 11-21 Procedures:, 10-2
Holders, optional, 4-5 Measurement Results
HOME key, 3-3 Geometry Test, 11-6
Menu
I Enhanced Tests, 11-1
ID Inventory, 12-1
Main, 5-1, 9-1, 12-1, 14-1
User, 10-8 Nuclides, 6-14
Installation, 4-1 Other, 6-2
Intended Use, 2-1 Screen Setup, 5-17
Inventory, 12-1 Select, 11-2
Selections, 3-4
adding to, 12-2 Setup, 5-2
deleting from, 12-13 Test Source, 6-4
making a kit, 12-7 Tests, 8-3, 11-1
Menu, 12-1 MENU key, 2-3, 3-3
printing, 12-13 Mo/Tc Limit, 4-8
withdrawing activity from, 12-11 Mo99
IVBT, 1-3, 1-4 Assay, 10-13
Background, 10-11
K Moly Assay, 4-8, 10-10
Keyboard, 3-1 CapMac or Canister, 6-11
Limit, 6-13
L Results, 10-14
Labels Selecting method, 6-11
multiplication factors, 1-4
Caution, 1-2
High Voltage, 1-3 N
Shipping, 15-16 NUCL key, 3-2, 10-3
Warning, 1-2 Nuclide
Line Filter, 2-5
Line Voltage, 2-5 keys, 3-2
Linearity Test, 7-1, 7-2, 7-4 specification, 10-3
Calicheck-defining, 6-27
definition, 6-23 INDEX April 16

i-2

CAPINTEC, INC. CRC-25R

Nuclides Two Strip Test, 11-18
adding, 4-8, 6-14 Quarterly Tests, 7-4
deleting, 6-18
Menu, 6-14 R
Radiochromatography, 11-15
Number / Letter keys, 3-3 Range
Numeric Data
limits, 2-6
entering, 3-4 recalibration, 1-5
Receiving Condition Examination, 4-1
O Regulatory Listings, 2-7
On / Off Switch, 2-4
Operational Setup, General, 4-7 Electrical, 2-7
Operational Summary, 4-9 EMC, 2-7
Operator ETL Listed, 2-7
Related Products, 15-15
Profile, 2-1 Remote (Legacy Systems Only)
Training, 2-2 Adding Nuclides, 6-31
Other Menu, 6-2 Nuclide Assignment, 6-29
Remove Nuclides, 6-30
P Requirements
Performance, 2-6 Environment, 2-4, 4-6
Power Requirements, 2-5, 4-6 Power, 2-5, 4-6
Preliminary Procedures, 2-4 Resolution
Pre-Set Nuclide keys, 10-3 Selecting, 10-6
Preventative Maintenance, 15-4
S
Quality Assurance Tests, 15-4 Safety, 1-1
PRINT key, 3-3 Safety Tips, 1-6
printer screen

None, 5-17 contrast, 5-17, 5-19
power requirements, 5-5 saver, 5-17, 5-18
RS-232, 5-6 setup, 5-17
selection, 5-5 Screen Setup Menu, 5-17
types, 4-8 Select Menu, 11-2
USB, 5-16 Selecting Resolution, 10-6
Printing, 5-4 Servicing, 15-4
Record of measurment, 10-9 Fuse, 15-6
Printing Inventory, 12-13 Setup
Profile General Operational, 4-7
Operator, 2-1 Setup Menu, 5-2
Program Flow, 2-3 Shipping, 15-16
Single Strip Test, 11-16
Q SOURCES key, 3-2, 10-5
QC Tests, 11-15 Standard Linearity Test, 11-7
Defining, 6-25
HMPAO Test, 11-21 Symbol Definitions, 1-1
MAG3 Test, 11-25 Syringe
Single Strip Test, 11-16 Measuring with, 11-2
Two Strips Test, 11-18 System Initialization, 5-1
Quality Assurance Tests, 7-3, 15-4 System Setup, 4-1
Quality Control, 11-15
HMPAO Test, 11-21 INDEX i-3
MAG3 Test, 11-25
Single Strip Test, 11-16

April 16

CAPINTEC, INC. CRC-25R

T Quarterly, 7-4
Table Yearly, 7-4
Tests Menu, 8-3, 11-1
Calibration Number Limits, 6-16, 10-5 Time
Disposal Information, 15-5 entering, 5-1
Test Source calibration activity limits, 6- TIME key, 3-2, 10-6
Training
8 Operator, 2-2
Tc99m Troubleshooting, 15-13
Two Strip Test, 11-18
Assay, 10-14
Technical Description, 2-4 U
Test Unpacking, 4-1
USB Port Settings, 6-31
Report, 7-2, 7-3, 8-9 User ID number, 10-8, 10-15
TEST Key, 3-2 User Key Assignment, 4-8, 6-2
Test Source, 4-8, 6-4 USER keys, 3-2, 10-3

calibration activity limits, 6-8 V
Constancy, 6-9 Voltage
Daily usage, 6-8
Entering Calibration Activity, 6-7 High, 1-3, 1-4
Entering Calibration Date, 6-6
Entering Serial Number, 6-6 W
Menu, 6-4 Warm Up Period, 2-4
Testing Withdrawing activity from Inventory, 12-11
Acceptance, 4-9, 7-1
Accuracy, 7-2, 7-3, 8-11 Y
Contamination, 7-3 Yearly Tests, 7-4
Daily, 7-2, 7-3, 8-3 Yes or No, 3-4
Diagnostics, 7-2, 7-4
Linearity, 7-2, 7-4
Quality Assurance, 7-3
Quality Control (QC), 11-15

i-4 INDEX April 16

CAPINTEC, INC. CRC®-25R

NEW PRODUCT WARRANTY

Conditions and Limitations

CAPINTEC warrants our products to be free from defects in material and
workmanship for a period of 24 months after delivery to the original buyer
(unless indicated otherwise). Our obligation under this warranty is
limited to servicing or adjusting products returned to our factory for that
purpose promptly upon any claim under this warranty, provided our
examination discloses to our satisfaction that the affected parts were
originally defective and have not been subjected to misuse, abuse,
mishandling or improper operation. This warranty extends to every part
of the product except batteries, fuses, ink, magnetic storage media,
toner, transistors, tubes or any other normally consumable item. In no
event shall we liable for transportation, installation, adjustment or any
other expenses which may arise in connection with such products or
their servicing or adjustment.

This warranty is expressly in lieu of any other express or implied
warranties, and we make no warranty that the products sold herein are
merchantable or are suitable for any particular purpose. The benefits of
this warranty shall extend only to the buyer and to none other. We shall
have no liability of any nature arising out of the use or application of the
product in conformity with this warranty. If the product shall fail to
perform in conformity with the warranty made herein, we shall be liable
solely for the repair and replacement of the product as provided
hereinabove, and shall have no other liability in respect of such failure or
performance, or any consequences therefrom, including, without
limitation, business impairment or loss, personal injury or property
damage.

No agent, employee, or representative of ours has any authority to bind
us to any representation or warranty concerning the product sold herein,
and unless a representation or warranty made by an agent, employee or
representative is specifically included herein, it shall not be enforceable
by the buyer. No waiver, alteration or modification of the foregoing
conditions shall be valid, unless made in writing and signed by an
executive officer of our corporation.

CAPINTEC, INC. CRC®-25R

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